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2 results

  • Relations between White Matter Maturation and Reaction Time in Childhood

  • Nadia Scantlebury, Todd Cunningham, Colleen Dockstader, Suzanne Laughlin, William Gaetz, Conrad Rockel, Jolynn Dickson, Donald Mabbott
  • Journal:
    Journal of the International Neuropsychological Society / Volume 20 / Issue 1 / January 2014
    Published online by Cambridge University Press:
    29 October 2013, pp. 99-112

  • White matter matures with age and is important for the efficient transmission of neuronal signals. Consequently, white matter growth may underlie the development of cognitive processes important for learning, including the speed of information processing. To dissect the relationship between white matter structure and information processing speed, we administered a reaction time task (finger abduction in response to visual cue) to 27 typically developing, right-handed children aged 4 to 13. Magnetoencephalography and Diffusion Tensor Imaging were used to delineate white matter connections implicated in visual-motor information processing. Fractional anisotropy (FA) and radial diffusivity (RD) of the optic radiation in the left hemisphere, and FA and mean diffusivity (MD) of the optic radiation in the right hemisphere changed significantly with age. MD and RD decreased with age in the right inferior fronto-occipital fasciculus, and bilaterally in the cortico-spinal tracts. No age-related changes were evident in the inferior longitudinal fasciculus. FA of the cortico-spinal tract in the left hemisphere and MD of the inferior fronto-occipital fasciculus of the right hemisphere contributed uniquely beyond the effect of age in accounting for reaction time performance of the right hand. Our findings support the role of white matter maturation in the development of information processing speed. (JINS, 2013, 19, 1–14)

  • Section II - Mood Disorders

  • Edited by Martha E. Shenton, Bruce I. Turetsky, University of Pennsylvania
  • Book:
    Understanding Neuropsychiatric Disorders
    Published online:
    10 January 2011
    Print publication:
    09 December 2010, pp -

  • Summary

    This chapter discusses recent structural neuroimaging studies that address the regions of interest in the proposed anterior limbic network model. Given the predominance of MRI in structural imaging of psychiatric disorders, the chapter also focuses on this imaging modality. First, longitudinal studies are needed to clarify how brain structures change within individual patients, with particular regard to the corresponding course of illness. Second, more sophisticated measures, such as diffusion tensor imaging (DTI) tractography or shape analyses, may more consistently define the subtle structural abnormalities that are likely in bipolar disorder and that may be missed with less-specific measures. Third, studies in young patients are critical given the typical adolescent onset of bipolar disorder and early course progression. Finally, integrating structural imaging with functional and neurochemical are the only ways to move morphometric imaging from high-priced and sophisticated phrenology to a better understanding of the neural basis of bipolar disorder.